KR20170143212A - A fishing collecting device having LED lamp - Google Patents

Abstract

The present invention relates to a light emitting diode (LED) fish attracting lamp device configured to allow heat generated in an LED fish attracting lamp to be transferred to a fish attracting lamp installation stand within a short time by closely attaching the LED fish attracting lamp to the outer circumferential surface of a hollow fish attracting lamp installation stand, to efficiently cool high heat generated by a high output of an LED when an LED fish attracting lamp using an LED as a light source is used. The LED fish attracting lamp device comprises: an LED module (120) including a printed circuit board (122) and a plurality of LEDs (121) arranged in a matrix form on the printed circuit board (122), and configured to emit light forward when power is supplied; a fish attracting lamp case (110) having the LED module (120) therein, having a heat radiation function, and including an installation stand coupling groove (111), which is an outer shape of a fish attracting lamp installation stand (31), on the rear side thereof; and an attachment hole (300) supporting the LED fish attracting lamp (100) from the rear side thereof to allow the fish attracting lamp installation stand (31) to be closely attached to the installation stand coupling groove (111) formed on the rear side of the fish attracting lamp case (110), wherein a heat conductive member is formed between the fish attracting lamp installation stand (31) and the attachment hole (300) and/or the installation stand coupling groove (111) between the LED fish attracting lamp (100) and the fish attracting lamp installation stand (31). In addition, the LED fish attracting lamp of the present invention further comprises a lens (200) and/or a reflection device (500) configured to emit an asymmetric light beam, thereby concentrating light on the sea surface near the sides of a fishing boat.

Description

FIELD OF THE INVENTION [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a light emitting diode (LED) pick-up device, and in particular, to use an LED pick-up lamp having a light emitting diode (LED) as a light source, And an LED earthing lamp is closely formed on the outer circumference of the earthing lamp mounting base, so that heat generated from the LED earring is transmitted to the earlobe in a short time.

BACKGROUND ART [0002] Today, various electrically stable light emitting devices have been developed by development of electric / electronic technology, and a typical light emitting device is a light emitting diode (LED).

Light emitting diodes (LEDs) are one of the solid state light emitting display devices and can be applied to various fields as well as monochromatic LEDs which emit red (R), green (G) and blue (B) A white light LED has been developed.

Applications of such LEDs include a light harvesting device for collecting meat by light.

However, in the case of a speaker using such an LED as a light source, there is a problem that a high heat is generated in order to generate a high output, so that a heavy heat sink must be attached in order to cool down during use.

Patent Document 1: Korean Published Patent Application No. 2010-0091353 (published on Aug. 19, 2010)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide an LED earpiece which is formed by closely attaching an LED earthing lamp to an outer circumferential surface of a hollow pinion mount stand, Device.

It is another object of the present invention to provide an LED pick-up device which can further include a lens configured to emit an asymmetrical light beam to an LED pick-up lamp and concentrate the light on the sea surface near the seam of the pick-up line.

Further, the present invention is to provide an LED headlamp apparatus capable of increasing the light diffusion efficiency with respect to the LED center light by constituting a protrusion protruding downward (LED forming direction) from the inner peripheral surface of the lens.

According to an aspect of the present invention, there is provided an LED headlamp comprising: a printed circuit board (122); and a plurality of LEDs (121) arranged in a matrix on the printed circuit board (122) An LED module (120) configured to radiate light forward; A filler case 110 having the LED module 120 therein and having a heat dissipating function and having a mounting groove engaging groove 111 in the outer shape of the beacon mount 31 at the rear side; And a mount 300 for supporting the LED headlamp 100 from the rear so that the speaker mount 31 is in close contact with a mount connecting groove 111 formed on the rear side of the holder case 110, And a heat conductive member is provided between the fixture lamp 100 and the fixture mount 31 and between the fixture 300 and the fixture fixture 31. [

Examples of the heat conduction member include a thermally conductive silicone 111b or thermal grease.

And a plurality of grooves are formed in the mounting table coupling groove 111 formed on the rear side of the holder case 110. [

In addition, the attaching member (300) fastened to the barbell stand (31) has a plurality of recesses.

The mounting bracket 111 is provided with a packing insertion groove 65 for inserting the packing 60. The heat conductive member is inserted into the mounting bracket groove 111 between the LED string lamp 100 and the bar- And the packing insertion groove 65 formed in the mounting groove engaging groove 111. [0040] As shown in FIG.

The LED module 120 includes a circuit wiring layer 41 of a copper foil, an LED 121 formed on the circuit wiring layer 41, a metal plate (aluminum metal) 43 formed under the circuit wiring layer 41, An insulating layer 42 formed between the circuit wiring layer 41 and the metal plate 43 to electrically isolate the circuit wiring layer 41 from the metal plate 43, And a control unit.

A nonconductor 44 is further provided between the LED module 120 and the case 110. The nonconductor 44 is made of heat-transferable material.

A bolt 91 is formed to penetrate through the LED module 120 (specifically, a PCB substrate of the LED module) and the nonconductor 44 to be fastened to the holder case 110, A ring-shaped insulating ring 92 coated with an insulating material and is electrically insulated between the LED module 120 and the holder case 110 by the insulating ring 92 do.

The LED headlamp apparatus further includes an AC-DC converter 150 for converting an AC power source to a DC power source. Heat generated from the AC-DC converter 150 is supplied to the speaker stand 31, And is cooled by the refrigerant flowing in the refrigerant circuit.

And a lens 200 positioned above the LED module 120 and having a cylindrical structure and configured to emit an asymmetrical light beam. The lens 200 has a unit cylindrical lens formed in a long column direction, And a plurality of LEDs are arranged in the column direction in each of the unit cylindrical lenses.

The present invention is characterized in that at least one LED is arranged not only in the column direction but also in the lateral direction within each unit cylindrical lens.

Further, the present invention is characterized in that the refrigerant is circulated in the bar-type mounting base (31) whose inside is hollow.

In addition, the present invention further comprises a temperature sensor 71 for detecting the temperature inside the LED stick-on-light device, and when the temperature inside the LED stick-on device is more than a set temperature, the LED stick- The circulation speed of the refrigerant circulating in the holder mounting base 31 is controlled by controlling the refrigerant circulation pump.

The present invention is characterized in that a bolt coupling hole 141 is formed in the rear of the LED string light 100 and a state in which the string light mounting stand 31 is tightly coupled to the mounting hole engaging groove 111 of the LED string 100, And the fastening bolt 140 constituting the fastening part 300 is fastened to the bolt fastening hole 141. The fastening bolt 140 is fastened to the bolt fastening hole 141 .,

The lens 200 includes an inner circumferential surface 211 for refracting light radiated from the LED 121 and an outer circumferential surface 212 for refracting light refracted at the inner circumferential surface 211, The inner circumferential surface 211 is a concave structure formed with a predetermined curvature, and the outer circumferential surface 212 is a convex structure formed with a predetermined curvature.

Further, the present invention is characterized by satisfying the following expression (1): α ≠ β, α> β or α <β, 40 ° ≤γ ≤100 °, and γ is a light beam irradiated (The angle of the light beam that has passed through the lens), alpha is a distance from the center of the LED 121 provided on the surface of the printed circuit board 122 to a side of the LED 121 Is the angle from the surface 21a of the printed circuit board 122 of the printed circuit board 122 to the portion 21b where the light is irradiated and β is the surface 22a of the printed circuit board 122 on the other side of the LED 121, To the portion (22b) where the light irradiation is performed.

And the inner circumferential surface 211 is formed with a fine protrusion pattern.

The inner circumferential surface 211 and / or the outer circumferential surface 212 of the lens 200 may have one or more curvatures.

As an example, the outer surface 212 may include a first surface having a first curvature, a first surface having a first curvature or a second surface having a second curvature different from the first curvature, A second surface having a second curvature different from the curvature and a third surface having a third curvature different from the second curvature.

The thickness of the lens 200 on which the first surface is located is denoted by T1, the thickness of the lens 200 on which the second surface is located is denoted by T2, the thickness of the lens 200 on which the third surface is located, The thickness of the lens 200 has a relationship of T1 > T3 > T2, or a relationship of T1 > T2 = T3.

The optical axis Lc irradiated from the LED module 120 may be inclined by a predetermined angle relative to the vertical axis.

The LED module 120 includes a plurality of LEDs 121 arranged in a strip-shaped printed circuit board 122 in a predetermined interval in a column direction, and the strip-shaped printed circuit board 122 is arranged in a lateral direction Are arranged in a plurality.

The light incident on the inner circumferential surface 211 of the concave lens 200 is irradiated from one or two or more LEDs 121.

In the present invention, when the LED pick-up device including the lens 200 is installed on the fishing boat 10, the thinner portion of the lens 200 is configured to be adjacent to the fishing boat string, Is configured so that the thick portion of the lens 200 is farther away from the string of the fishing boat than the thin portion of the lens 200 relatively.

The present invention is characterized in that when the LED flasher device including the lens 200 is installed on the fishing boat 10, the thick part of the lens 200 is configured to be adjacent to the fishing boat string, The thickness of the lens 200 is relatively far from the string of the fishing line, rather than the thickness of the lens 200.

In addition, the present invention is characterized in that, when the LED pick-up device is installed on the fishing boat 10, the LED pick-up device is installed at an angle of 15 to 50 degrees toward the sea surface with respect to the vertical direction of the sea surface.

The present invention is characterized in that the center of the concave portion of the inner circumferential surface 211 and the center of the convex portion of the outer circumferential surface 212 are not aligned on the straight line but are shifted from each other.

Further, the present invention is characterized in that a plurality of the LEDs 121 are arranged in the column direction and the lateral direction with respect to each unit cylindrical lens 200.

The protrusion 400 may be formed of the same material as the lens 200 and may be integrally formed with the lens 200. The protrusion 400 may protrude downward from the inner circumference of the lens 200, Is formed.

The center portion 401 of the protrusion 400 is positioned directly above the central portion 402 of the LED 121 so that the divergent light of the central portion 402 of the LED 121 is reflected by one of the protrusions 400 And the reflection and refraction are made via the point.

The protrusion 400 may be formed of the same material as the lens 200 and may be integrally formed with the lens 200. The protrusion 400 may protrude downward from the inner circumference of the lens 200, And the protrusion 400 is formed on at least one of the first to third surfaces of the lens 200. The center portion 401 of the protrusion 400 is formed at a center 402 of the LED 121 ) Of the upper surface of the housing.

The protrusion 400 may be formed of the same material as the lens 200 and may be integrally formed with the lens 200. The protrusion 400 may protrude downward from the inner circumference of the lens 200, And the protrusions 400 are formed in a length corresponding to the number of the LEDs 121 in the transverse direction and the protrusions 400 are formed in correspondence to the LEDs 121 Respectively.

The cross section of the lens 200 in the lateral direction (y-axis direction) is asymmetrical and the longitudinal direction (column direction, x-axis direction) of the lens 200 is symmetrical in the left and right direction. Is an aspherical surface or a spherical surface.

In addition, the present invention is characterized in that the LED 121 is a blue or a cyan LED.

The protrusion 400 is characterized in that a fine protrusion pattern is formed.

The fine protrusion pattern on the protrusion 400 and the fine protrusion pattern on the protrusion 400 are different from each other.

The LED headlamp 100 of the present invention further includes a reflection device 500 configured to emit an asymmetrical light beam and the reflection device 500 is positioned on the LED module 120 .

The LED module 120 includes a printed circuit board 122 and a plurality of LEDs 121 arranged in a row and a column direction on the printed circuit board 122. The reflective device 500 is provided with a light- The light guiding groove 510 is formed to have a larger inclination angle (an asymmetrical inclination angle) than the light guiding groove 510, and the reflecting side walls of the light guiding groove 510 have different inclination angles.

The light guide groove 510 of the reflection device 500 is formed to be long in the longitudinal direction (column direction), and the light guide groove 510 of the reflection device 500 is formed to be long in the longitudinal direction A plurality of LEDs (LEDs) 121 are arranged at regular intervals in the longitudinal direction (column direction) on the bottom surface of the light guide groove 510.

1 of the first reflective sidewall 521 and the inclined angle 2 of the second reflective sidewall 522 of the light guide groove 510 are 20 to 70 ° and 30 to 90 °, .

The second reflective sidewall 522 is configured to be adjacent to the string (center) of the fishing boat 10 relative to the first reflective sidewall 521 and the inclination angle 2 of the second reflective sidewall 522 is less than the first reflection Is larger than the inclination angle? 1 of the side wall 521.

The first reflective sidewall 521 is configured to be adjacent to the string (center) of the fishing boat 10 relative to the second reflective sidewall 522 and the inclination angle 2 of the second reflective sidewall 522 is less than the first reflection Is larger than the inclination angle? 1 of the side wall 521.

In addition, the present invention is characterized in that the optical axis (Lc) of the LED module 120 is inclined by? Relative to the vertical axis.

Further, in the present invention, a plurality of LEDs 121 are arranged in the longitudinal direction (column direction) at regular intervals on the strip-shaped printed circuit board 122,

And a plurality of the strip-shaped printed circuit boards 122 are arranged in the lateral direction (y-axis direction).

Further, the present invention is characterized in that a means (seating hole) for seating the LED 121 is further formed on the bottom surface of the light guide groove 510.

As described above, according to the present invention, since the LED pick-up lamp is closely formed on the outer peripheral surface of the hollow pick-up lamp stand, the high heat generated in the LED pick-up can be efficiently dissipated through the pick-up stand quickly.

Further, the LED pick-up lamp of the present invention further includes a lens and / or a reflection device configured to emit an asymmetrical light beam, so that light can be concentrated on the sea surface near the string of the fishing boat.

In addition, since the light distribution control can be performed through such a lens, there is a cost-saving effect such that installation of a separate lamp or the like is unnecessary.

In addition, the present invention can increase the light diffusion efficiency with respect to the LED central light by constituting the protrusion protruding downward (LED forming direction) from the inner circumferential surface of the lens.

1 is a perspective view of a fishing boat according to the present invention,
Fig. 2 is a perspective view showing a main part of the LED pick-up lamp of Fig. 1,
Figs. 3a and 3b are a simplified vertical cross-sectional view of a fishing boat of the prior art and of the present invention,
FIG. 4 and FIG. 5 are exploded perspective views showing a front view of a LED headlight installed in a headlight mount according to an embodiment of the present invention;
FIG. 6 is an assembled perspective view of FIG. 4 and FIG. 5,
7A and 7B are an exploded perspective view and an assembled perspective view, respectively, of a rear view of the LED headlamp installed in the headlamp mount according to the embodiment of the present invention.
8 is a perspective view of a lens according to an embodiment of the present invention,
9 is a cross-sectional view along the line A-A 'in Fig. 8,
10 is a cross-sectional view of a lens according to another embodiment of the present invention,
FIG. 11 is a cross-sectional view of the unit cylindrical lens of FIG. 9 further including a projection;
12A is a perspective view showing the unit cylindrical lens of FIG. 11, FIG.
FIG. 12B is a cutaway perspective view showing the unit cylindrical lens of FIG. 11,
FIG. 13 is a cross-sectional view of the unit cylindrical lens of FIG. 10 further including a projection;
Fig. 14 is a sectional view of the LED barrel adopting the unit cylindrical lens of Figs. 11 and 12,
Fig. 15 is a sectional view of the LED pick-up lamp having the lens structure of Fig. 11 installed on the fishing boat, Fig.
Fig. 16 is a cross-sectional view showing that fine protrusion patterns are formed on the inner peripheral surface of Fig. 9,
Fig. 17 is a cross-sectional view showing that fine protrusion patterns are formed on the inner peripheral surface of Fig. 10,
Fig. 18 is a cross-sectional view showing that fine protrusion patterns are formed on the inner peripheral surface of Fig. 11,
Fig. 19 is a cross-sectional view showing that fine protrusion patterns are formed on the inner peripheral surface of Fig. 13,
Fig. 20 is a cross-sectional view showing that a protrusion pattern is formed on the protrusion of Fig. 11,
FIG. 21 is a cross-sectional view showing that the protrusions of FIG. 13 are formed with fine protrusion patterns,
FIG. 22A is a cross-sectional view showing an asymmetrical form of light beam irradiation pattern emitted from the LED pick-up device according to the present invention,
22B is a photograph showing the shape of the light beam emitted from the LED headlamp apparatus according to the present invention,
22C is a simulation light distribution diagram using optical software to verify the effect of the LED bulb device according to the present invention,
Fig. 23 is a perspective view of Fig. 6,
24 is a detailed sectional view of an LED module and a holder case according to an embodiment of the present invention,
25 is a detailed sectional view of an LED module and a holder case according to another embodiment of the present invention,
26 is a block diagram showing the control of the LED pick-up device or the refrigerant circulation pump according to the measurement result of the temperature sensor,
27 is a perspective view of a reflection device according to an embodiment of the present invention,
28 is a sectional view taken along the line B-B 'in Fig. 27,
29 is a sectional view of a reflection device according to another embodiment of the present invention,
Fig. 30 is a sectional view of the LED pick-up lamp to which the reflection device of Fig. 28 is applied,
31 is a cross-sectional view of a state in which an LED pick-up lamp to which the reflection device of Fig. 28 is applied is mounted on a fishing boat.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a fishing boat 10 according to the present invention, and FIG. 2 is a perspective view showing a main part of the LED pick-up lamp 100 of FIG.

In the present embodiment, it corresponds to a pair of string fixture mounts 31 in two rows.

That is, as shown in the figure, one or more vertical supports 11 are formed on the fishing boat 10, and two rows of bar table attachments (two opposite sides) of the fishing boat 10 31).

In this specification, the headlamp mount 31 constituting one side row (first row) of the fishing boat 10 is referred to as a "first headlamp mount", and the headlamp mount 31 composed of the other side row (second row) It will be called the "second spearhead mount".

The present invention is installed on both sides (both sides) of the fishing boat 10 in the direction in which the first and the second earbar mounting bases 31 and 31 are parallel to each other.

A gap holding member 51 is formed between the first and second speaker mounts 31 and 31 so that the first and second speaker mounts 31 and 31 ) Are maintained at a constant interval, that is, parallel.

Further, the joint unit 50 connects the first and second bar-like lighting mounts 31, the vertical supports 11 and the gap holding members 51 at one point.

A plurality of LED headlamps (100) are fixedly installed on the outer circumferential surface (212) of the first and second speaker mounting base (31).

In the present invention, the LED headlamps 100 are arranged such that the light emitted from the LED headlamps 100 located in the respective columns is directed to the outside of the fishing line 10.

 In the embodiment of the present invention, the first and second bar-type lighting fixtures 31 and 31 are configured in parallel, but the present invention is not limited thereto. That is, the first and second bar-type lighting mounts 31 and 31 may not be parallel to each other depending on the structure of the fishing boat 10 and the usage pattern thereof.

In addition, in the embodiment of the present invention, the bar fixture mount 31 provided on the fishing boat 10 may be constituted by two rows as shown in FIG. 2, but it may be composed of one row as the case may be.

In addition, a connecting pipe 32 may be installed between the first and the second bar-type lighting fixture 31 and 31.

In other words, one connection pipe 32 is formed between one end of the first speaker mount 31 and one end of the second headlight mount 31, and the other end of the first speaker mount 31 and the second earlight mount 31 may be constituted so as to form a closed loop as a whole.

Also, in the present invention, cooling water (or refrigerant) flows through one vertical support 11 and cooling water is discharged through another vertical support 11, at which time a pump can be used.

Further, it is preferable that a coupling member 33 is formed between the first and second speaker mounting base 31 and the connecting pipe 32.

In addition, the present invention may be configured such that the first and second bulb holder 31 and the connecting pipe 32 are hollow and the refrigerant is circulated in the hollow. This is for rapid cooling of the LED pick-up lamp 100 installed on the first and second spearhead mounts 31.

In addition, the present invention may constitute a supply pipe (not shown) for supplying the refrigerant to the first and second bulb holder 31 and a discharge pipe (not shown) for discharging the heated refrigerant to the outside.

In addition, the present invention can also provide the LED headlamp 100 on the outer circumferential surface 212 of the connecting pipe 32.

Accordingly, the present invention is capable of fishing operations on both sides of the fishing boat 10 as well as on the front and rear sides.

Figs. 3A and 3B are simplified longitudinal sectional views of a fishing boat 10 of the conventional fishing boat 10 of the present invention.

A vertical support 11 is installed on the fishing boat 10 and a plurality of horizontal supports 12 are installed on the vertical support 11. The LEDs 13 are mounted on both ends of the horizontal support 12, The child support light 100 is installed.

However, conventionally, as shown in Fig. 3A, light is concentrated on the sea surface 18 at a position (point A) far from the strings of the fishing boat 10. Accordingly, the fish must be focused on the sea surface 18 at a position near the fishing ground 10, such as squid fishing.

The LED headlamp 100 of the present invention is provided with a lens 200 and / or a reflecting device 500 configured to irradiate an asymmetrical light beam so that the sea level of the fishing line 10 near the string (Refer to FIG. 3B)

When the LED headlamp 100 according to the present invention is installed on the fishing boat 10, the LED headlamp 100 is rotated at a predetermined angle (?) Toward the sea surface with respect to the vertical direction of the sea surface (i.e., (See FIG. 3B). Here, when the LED stick-up light 100 is inclined to less than 15 degrees with respect to the vertical direction of the sea surface (that is, the vertical support formation direction) The light from the fishing line is directed too far from the fishing line, so the picking effect is lowered and the energy loss is too large. In addition, when the LED headlamp 100 is tilted by more than 50 degrees with respect to the vertical direction of the sea surface (i.e., the vertical support forming direction), the light irradiated from the LED headlight during the rolling of the fishing boat illuminates the inside of the fishing boat, As a result, not only the light efficiency is lowered but also the work efficiency is lowered due to the operator's eyes being drowned.

FIGS. 4 and 5 are perspective views illustrating the LED headlamp 100 installed on the barbed stand according to an embodiment of the present invention. FIG. 6 is a perspective view of the combined assembly of FIGS. 4 and 5, 7b are an exploded perspective view and an assembled perspective view of the LED headlamp 100 installed on the headlamp mount according to the embodiment of the present invention.

First, the fishing rod mounting base 31 will be described. The fishing rod mounting base 31 is a pipe having a hollow portion formed therein with a predetermined length. The pipe is provided on both sides (both sides) of the fishing boat 10 as described above.

Both ends of the barrel stand 31 may be configured to be hermetically closed, but may be connected so that the internal refrigerant can be circulated.

Aluminum, copper, iron, or the like may be used as the material of the bar code mounting base 31, and it is preferable to use stainless steel in consideration of the life, durability and tensile strength.

As the refrigerant, a liquid such as cooling water (for example, fresh water, sea water, etc.), cooling oil or antifreeze liquid and the like may be used, or a gaseous cooling gas or the like may be used.

The LED headlamp 100 is formed on one outer circumferential surface 212 of the barb mounting stand 31 and an attachment 300 for supporting the LED headlamp 100 from the rear is formed on the other outer circumferential surface 212 of the barb mounting stand 31 .

The LED headlamp 100 includes an earphone case 110, an LED module mount 130, and an LED module 120 as an example.

The holder case 110 is, for example, a generally hexahedron shaped in the longitudinal direction, open at the front, and hollow inside. (LED module 120, etc.) of the LED stick-up light 100 are installed in the empty part.

Further, the holder case 110 is made of a metallic material (for example, aluminum or the like) excellent in heat transfer and has a heat radiation function.

An AC-DC converter 150 for converting an alternating current (AC) to a direct current (DC) may be formed inside the holder case 110.

A mounting bracket groove 111 (hereinafter, also referred to as a "pipe coupling groove") is formed on the rear side of the holder case 110 so that the bar holder 31 can be tightly coupled with the LED bar 100.

The mounting base engaging groove 111 may be formed in the center of the rear side of the holster case 110 but may be formed at a position slightly deviated from the center of the back side of the holster case 110 as shown in the drawing.

The shape of the mounting table engaging groove 111 is preferably made of an outer shape (for example, a circular shape, a semicircular shape, or the like) of the pinion mounting base 31.

The LED module seating portion 130 may protrude forward from the inside of the holder case 110, and the LED module 120 is seated on the protruded portion.

The LED module seating portion 130 is formed to be long in the longitudinal direction of the pop holder case 110, that is, in the pipe longitudinal direction, and the upper portion thereof is configured to be flat.

In addition, the LED module seating portion 130 may be disposed at a position closest to the mounting base engagement groove 111. Accordingly, the present invention can improve the cooling efficiency of the LED module 120 mounted on the LED module seating part 130.

The LED module 120 is seated in the LED module seating part 130, and a plurality of LEDs 121 are arranged at regular intervals to emit light forward when power is supplied.

The present invention is characterized in that it is provided with a deviation preventive means for preventing the pecker stand 31 from being detached from the mount engaging groove 111 in a state where the harness stand 31 is coupled to the mount engaging groove 111 of the LED headlight 100 .

The detachment preventing means may include a bolt coupling hole 141 at the rear of the LED stringer lamp 100 and may be formed in a state in which the stringer attachment base 31 is coupled to the mounting hole coupling groove 111 of the LED stringer lamp 100, And the fastening bolt 140 formed in the fastening part is fastened to the bolt fastening hole 141. [ By providing such departure preventing means, the present invention can improve the cooling efficiency.

In an embodiment of the present invention, two bolt coupling holes 141 are provided on the upper and lower sides with respect to the mounting table coupling groove 111, respectively.

The attachment part 300 is bended at its center part, and holes are formed at both edges to fasten the fastening bolts 140.

Thus, in the present invention, the fastening bolt 140 is engaged with the bolt coupling hole 141 of the LED headlamp 100 while supporting the barbed mount 31 at the rear in a state where the fastening bolt 140 is fitted in the hole of the attachment hole 300. The LED headlamp 100 is closely attached to the outer circumferential surface 212 on one side of the speaker mounting base 31 with respect to the speaker mounting base 31 and the mounting hole 300 is closely attached to the outer circumferential surface 212 of the other side of the speaker mounting base 31 .

The present invention is characterized in that a heat conductive member (for example, thermal grease or the like) is provided between a portion of the mounting groove engaging groove 111 between the LED earthing lamp 100 and the barrel mounting base 31 and / or between the mounting hole 300 and the barrel mounting base 31 It is preferable to

In the present invention, the LED module 120 is disposed on the upper part of the LED module mounting part 130, and the mounting table mounting groove 111 of the LED pick-up lamp 100 is filled with (or circulated) 31 and the LED holder 100 is fixed to the holder mounting base 31 by using the attachment 300. [ In addition, the present invention constituted the AC-DC converter 150 inside the holder case 110.

When the LED headlamp 100 is turned on in this state, the LED module 120 of the LED headlamp 100 and the AC-DC converter 150 generate heat. This heat is transmitted to the speaker mount 31 through the LED module seat 130 and cooled by the refrigerant in the speaker mount 31

Most of the heat is cooled in the coolant, and some heat is released through the headlamp mount 31.

In addition, the present invention may also be configured such that the refrigerant (water or the like) is circulated in the LED headlamp 100 so as to be cooled.

As another example of the departure preventing means, a fastening bolt penetrating from the inner side to the rear side of the LED headlamp 100 and a headlamp mounting bracket 31 are coupled to the mounting bracket groove 111 of the LED headlamp 100, And a nut coupled to the fastening bolt.

Further, the present invention further includes a lens 200 capable of providing high-efficiency light distribution.

The lens 200 is configured to have asymmetric light distribution characteristics (asymmetrical illumination direction) so that the light emitted from the LED 121 of the LED module 120 is focused on the sea surface 18 near the strings of the fishing line 10 (See FIG. 3B)

The LED module 120 includes a printed circuit board (PCB) 122 and a plurality of LEDs 121 arranged on the printed circuit board 122 in the directions of M rows and N columns (where M and N are natural numbers) .

Specifically, the LED module 120 is formed on a printed circuit board 122 having a strip shape (unit), which is elongated in the longitudinal direction (column direction, x-axis direction) A plurality (1 M) of LEDs 121 are arranged in the horizontal direction (the axial direction), and a plurality of (M) LEDs 121 are arranged in the lateral direction Structure. The LED module 120 includes a plurality of LEDs 121 arranged in a matrix of M rows and N columns (M × N (where M and N are natural numbers)) on a rectangular printed circuit board 122 It is a structure. In one embodiment of the present invention, M is 4 and N is 10, as shown in Figs.

 The structure of the LED module 120 is designed so that the optical refraction of the lens 200 located above the LED module 120 is efficiently performed.

In addition, the present invention may further comprise a packing insertion groove 65 for inserting a ring-shaped packing 60 into a mounting base engaging groove 111 of the LED headlamp 100.

After the packing 60 is inserted into the packing insertion groove 65, silicone for heat transfer (reference numeral 111b in FIG. 14) is applied to the mounting table engaging groove 111 corresponding to the inside of the packing 60, . This is to improve the heat transfer performance.

The packing 60 serves to prevent the heat conductive silicone 111b from leaking to the outside and to maintain the tightness between the bar holder 31 and the LED bar 100. [

The packing 60 is inserted into the packing insertion groove 65 formed in the mounting table engaging groove 111 and the thermally conductive silicone is inserted into the mounting table engaging groove 111 corresponding to the inside of the packing 60 111b, and then, the bar holder mounting base 31 is engaged with the mounting base engaging groove 111. [ The LED headlamp 100 is supported from the rear by using the attachment 300 so that the headlamp mount 31 is closely attached to the mounting bar coupling groove 111 formed on the rear side of the holder case 110. [ At this time, the fastening bolt 140 formed on the attachment 300 may be coupled to the bolt coupling hole 141. 6 and 7B.

Thus, the present invention is characterized in that the bar-like mounting base 31 is formed in close contact with the mounting base engaging groove 111 and is made of silicon (silicon) between the LED bar-like lamp 100 and the bar holder stand 31 by the packing 60 and the heat- The heat generated in the LED pick-up lamp 100 is quickly cooled by the refrigerant in the pick-up stand 31 as the portion to be coated 111b becomes a vacuum state.

In an embodiment of the present invention, the packing 60 is composed of a single packing, but it may also be configured as a double or triple packing.

Further, in the embodiment of the present invention, the heat conductive silicone 111b is used as the heat conductive member, but thermal grease can be used without being limited thereto.

FIG. 8 is a perspective view of a lens 200 according to an embodiment of the present invention, and FIG. 9 is a cross-sectional view taken along line A-A 'of FIG. 8, and shows a unit cylindrical lens in FIG. That is, as an example in Fig. 8, four unit cylindrical lenses having the structure as shown in Fig. 9 are arranged in the lateral direction (y-axis direction).

As shown in Figs. 8 and 9, the lens 200 of the present invention is configured to irradiate (emit) an asymmetric light beam.

Specifically, the lens 200 includes an inner circumferential surface 211 for refracting the light radiated from the LED 121 and an outer circumferential surface 212 for refracting the refracted light from the inner circumferential surface 211 (secondarily) . The lens 200 is located above the LED module 120 and has a cylindrical structure that is elongated in the longitudinal direction (column direction, x-axis direction). Here, the outer circumferential surface 212 of the lens 200 corresponds to the surface of the lens 200.

The inner circumferential surface 211 of the lens 200 is a concave structure formed with a predetermined curvature and the outer circumferential surface 212 of the lens 200 is a convex structure formed with a predetermined curvature. The inner circumferential surface 211 of the lens 200 is an incident surface of the light irradiated by the LED 121 and the outer circumferential surface 212 of the lens 200 is the exit surface of the light that has passed through the lens 200. The center of the inner circumferential surface 211 may be formed in the most concave shape, and the center of the outer circumferential surface 212 may be formed in the most convex shape. The shape of the inner peripheral surface 211 and / or the outer peripheral surface 212 may have an elliptical or circular shape. 9, the center of the concave portion of the inner circumferential surface 211 and the center of the convex portion of the outer circumferential surface 212 are not located on a straight line but are shifted from each other.

Accordingly, the light emitted from the LED 121 goes straight through the first medium (e.g., air or vacuum) between the lens 200 and the LED 121, and then passes through the inner surface 211 of the lens 200, Refracted, and refracted at the outer peripheral surface 212 of the lens 200 through the second medium (lens 200) to be irradiated into the air.

Examples of the material of the lens 200 as the second medium include glass, polymethacrylate, polycarbonate (PC), polymethyl methacrylate (PMMA), cycloolefin copolymer Polymer (Cyclo Olenfin Copolymer; COC) or other plastics.

The LED 121 provided on the printed circuit board 122 may be arranged so as to be located directly below the center of the inner circumferential surface 211 of the lens 200, It may be provided directly below or at a position spaced apart from one side or the other side. 9, the LED 121 is positioned directly under the center of the inner circumferential surface 211 of the lens 200. 9, the central portion of the concave of the inner circumferential surface 211 and the LED 121 (or the vertical axis of the LED) are located on a straight line.

The inner circumferential surface 211 and / or the outer circumferential surface 212 of the lens 200 may have one or P curvature (where P is a natural number of 2 or more).

As a first embodiment, the outer circumferential surface 212 of the lens 200 can be configured to have one radius of curvature. The inner circumferential surface 211 of the lens 200 may be configured to have a single curvature like the outer circumferential surface 212 of the lens 200. [

Further, as a second embodiment, the outer circumferential surface 212 of the lens 200 may be composed of a first surface having a first curvature and a second surface having a second curvature different from the first curvature. Similarly, the inner circumferential surface 211 of the lens 200 may have the first and second surfaces having different curvatures as the outer circumferential surface 212 of the lens 200.

In the third embodiment, the outer surface 212 of the lens 200 has a first surface (a) having a first curvature and a second surface (b) having a second curvature different from the first curvature , And a third surface (c) having a third curvature different from the second curvature (see FIG. 9). Similarly, the inner circumferential surface 211 of the lens 200 may have the first, second, and third surfaces having different curvatures as the outer circumferential surface 212 of the lens 200.

The thickness of the lens 200 of the present invention is not constant uniformly from one side to the other side. This is for the light refracted at the outer peripheral surface 212 of the lens 200 to have an asymmetrical irradiation (emission) direction. For example, the thickness T1 of the lens 200 on which the first surface a of FIG. 9 is located, the thickness T2 of the lens 200 on which the second surface b is located, and the thickness T3 of the lens 200 in which the cyan (c) is located are different from each other. The thicknesses T1, T2 and T3 of the lens 200 may be a distance between the outer circumferential surface 212 and the inner circumferential surface 211 of the lens 200. [

In an embodiment of the present invention, the thickness of the lens 200 gradually decreases from one side (corresponding to the left in the drawing) of the lens 200 to the center side (convex portion) of the lens 200 as shown in FIG. 9 (T1> T2), the lens 200 is configured such that the thickness of the lens 200 gradually increases from the center side (convex portion) of the lens 200 to the other side (corresponding to the right side in the drawing) of the lens 200 ), Where T1 can be designed larger or smaller than T3. Therefore, the thickness of the lens can be designed so that T1> T3> T2 or T3> T1> T2. The thickness of the lens can be designed so that T1> T2> T3 or T2> T1> T3 or T2> T3> T1 or T3> T2> T1. The thickness of the lens can be designed so that T1> T2 = T3 or T2> T1 = T3 or T3> T1 = T2. T1 represents the thickness of one side of the lens, for example, the thickness of the first surface (a) of the lens outer circumferential surface, T2 represents the thickness of the lens center portion, for example, the thickness of the second surface (b) Represents the thickness of the other side of the lens, for example, the thickness of the third surface (c) of the lens outer peripheral surface.

The outer circumferential surface 212 and the inner circumferential surface 211 of the lens 200 have two curvatures as in the third embodiment (when P is 3) and the second embodiment (when P is 2) The thicknesses of the first and second surfaces of the lens 200 can be designed differently. Similarly, even when the P is composed of a surface having a curvature of 4 or more, the thickness of each surface of the lens 200 can be designed differently.

More specifically, the light refracted by the outer circumferential surface 212 of the lens 200 has an asymmetrical irradiation (emission) direction. As an example, the vertical axis of the LED 121 The emitted light is refracted at the outer circumferential surface 212 of the lens 200 and irradiated (emitted) into the air, assuming that light is emitted from the LED 121 in the direction of 30 degrees leftward and rightward 30 degrees, respectively , And the angles at which refraction (or irradiation) occur are different from each other. This is due to the difference in thickness and curvature of the lens 200 and the position of the LED 121.

The lens 200 of the present invention is installed so that the convex surface of the outer circumferential surface 212 of the lens 200 is directed to the sea side from the fishing boat 10.

A plurality of LEDs (LEDs) 121 are arranged at regular intervals in the longitudinal direction (column direction, x-axis direction) below the inner circumferential surface 211 of the lens 200.

In addition, the optical axis irradiated from the LED module 120 may be inclined at a predetermined angle relative to the vertical axis. For example, in general, the irradiation angle of the LED 121 is set to 60 degrees (120 degrees) in the left and right directions with respect to the vertical axis. In one embodiment of the present invention, 90 degrees to the right, or 30 degrees to the left 90 degrees. Here, the vertical axis represents the vertical (90 degrees) direction with respect to a predetermined point (e.g., LED) on the surface of the printed circuit board 122.

Further, the present invention is characterized in that the cylindrical lens 200 formed long in the longitudinal direction (column direction, x axis direction) is mounted on the printed circuit board 122 in the longitudinal direction (band) It may be configured to be detachable. This is for facilitating the replacement of the lens 200.

Accordingly, the lens 200 of the present invention having the above-described structure can control the light distribution of light emitted from the plurality of LEDs 121. [

10 is a cross-sectional view of a lens 200 'according to another embodiment of the present invention.

Up to now, the light incident on the inner circumferential surface 211 of the concave lens 200 was irradiated from one LED 121.

However, the present invention is not limited thereto, and it may be configured to be irradiated from the two or more LEDs (three LEDs in Fig. 10) to the inner peripheral surface 211 of the lens 200 '. The other configurations are the same as those described in the description of Figs.

As described above, the installation cost can be reduced by providing two or more LEDs 121 on one cylindrical lens 200 '.

11 is a cross-sectional view of the unit cylindrical lens 200 of FIG. 9 further including the projection 400, and FIG. 12A is a perspective view of the unit cylindrical lens 200 of FIG. Fig. 12B is a perspective view of the unit cylindrical lens 200 of Fig. 12A cut in a longitudinal direction (x-axis direction), and is a cutaway perspective view showing the unit cylindrical lens 200 of Fig. 12A. 13 is a cross-sectional view further including the projection 400 on the lens 200 of FIG.

The embodiment of Fig. 11 further includes the projection 400 in the configuration of the embodiment of Fig.

The protrusion 400 protrudes downward from the inner circumferential surface of the lens 200, that is, in a direction in which the LED 121 is formed.

The protrusion 400 is formed of the same material as the lens 200 and is formed integrally with the lens 200.

It is preferable that the central portion (the most convex portion) 401 of the projection 400 is located on the straight line with the central portion (convex portion) 402 of the LED 121. The central portion 401 of the projection 400 is preferably provided directly above the central portion 402 of the LED 121 and spaced apart from the central portion 402 of the LED 121 by a predetermined distance . This is to cause the divergent light of the LED central portion 402 to be reflected and refracted through one point of the projection 400.

The projections 400 may be formed on at least one of the first to third surfaces a to c of the lens 200. The protrusion 400 may be formed on only one of the first surface a, the second surface b, and the third surface c of the lens 200 as the first embodiment. As a second embodiment, the protrusions 400 may be formed on the first surface (a) and the second surface (b) of the lens 200 or may be formed on the second surface (b) (c). As a third embodiment, the projections 400 may be formed on the first to third surfaces (a to c) of the lens 200 simultaneously. When the lens 200 is simultaneously formed on two or more surfaces of the lens 200, it is preferable that the plurality of protrusions 400 are spaced apart from each other by a predetermined distance.

In the embodiment shown in Fig. 11, the projection 400 is formed on the second surface (b) as compared with the embodiment shown in Fig. Accordingly, in the embodiment of Fig. 11, the thickness T2 of the lens 200 in which the second surface b is located is larger than in the embodiment of Fig.

The protrusions 400 may be elongated in the column direction (x-axis direction), or a plurality of protrusions 400 may be spaced a predetermined distance in the column direction (x-axis direction). In the latter case, it is preferable that the protrusions 400 are located directly above the LEDs 121.

Likewise, the lens 200 'of the form as shown in FIG. 10 can also constitute the projection 400 described in the description of FIG. At this time, the protrusions 400 can be formed by the number of the LEDs 121 arranged in the lateral direction (y-axis direction).

13, when three LEDs 121a, 121b, and 121c are arranged in the column direction (x-axis direction) in one unit cylindrical lens 200 ' The protrusions 400a, 400b, and 400c may be formed at positions corresponding to the LEDs 121a, 121b, and 121c, respectively, as shown in FIG. More specifically, the first protrusion 400a is positioned in the upper right chamber of the LED 121a in the first row, the second protrusion 400b is located in the upper right chamber of the LED 121b in the second row, And the third projection 400c is positioned in the upper-right room of the first projection 400a. At this time, the protrusions 400a, 400b and 400c may be elongated in the column direction (x-axis direction), or a plurality of the protrusions 400a and 400b may be spaced a predetermined distance in the column direction (x-axis direction)

As described above, the light diffusion efficiency can be increased as compared with that shown in FIG. 9 by further configuring the protrusion 400 projecting downward (LED forming direction) from the inner peripheral surface of the lens 200 or 200 '. Specifically, the light emitting pattern of the LED 121 has a Gaussian distribution in which the light distribution is concentrated at the central portion as compared with the surroundings, and the central light of the LED 121 is much stronger than the ambient light of the LED 121 Which causes glare and light pollution due to glare. Particularly, the peripheral portion is less effective than the central portion due to darkness. However, as the protrusions 400 (400a to 400c) are formed in the lenses 200 and 200 'as shown in FIGS. 11 and 12, light concentration in the central portion of the LED is relaxed and light is uniformly distributed do. Thus, the present invention can maximize the picking efficiency at the sea surface.

Fig. 14 is a sectional view of the LED headlamp 100 employing the cylindrical lens 200 of Figs. 11 and 12. Fig.

The LED headlamp 100 of the present invention includes a lamp configured to irradiate light forward, a plate for fixing the lamp, and a projection 400 for emitting the light output from the lamp as asymmetric light and maximizing the light dispersion efficiency And the lens 200 formed.

Here, the lamp may be a light source itself fixed to the plate or may have a configuration including a light source (e.g., an LED light source) and an LED module 120.

Examples of the light source include an incandescent lamp, a gas lamp, and a fluorescent lamp as well as the LED light source described in FIGS. 4 to 10.

Further, the plate is, for example, a planar type LED module 120 having a plurality of LED light sources on its front side.

The lens 200 is configured to have an asymmetric light distribution characteristic such that the light emitted from the LED 121 of the LED module 120 is focused on the sea surface 18 near the string of the fishing line 10.

The detailed description of the structure of the lens 200 and the like has been made heretofore and will be omitted.

Further, in the present invention, as shown in a partially enlarged view (circular display) in Fig. 14, a plurality of grooves can be formed in the mounting table engaging groove 111 formed on the rear side of the holder case 110. [ This groove is formed to increase the contact area. Thus, when the thermally conductive member, for example, the heat conductive silicone 111b is applied to the mounting base engaging groove 111 between the LED headlamp 100 and the barrel mounting base 31, the groove formed in the mounting base engaging groove 111 The thermally conductive silicon 111b is filled. As the thermally conductive silicone 111b is filled in the groove, the contact area between the holder case 110 of the LED holder 100 and the holder mounting base 31 is increased, and the thermal conductivity of the heat conductive silicone 111b is increased. It will not come out well. As a result, the heat transfer performance is enhanced, and the heat radiation performance of the LED bulb holder of the present invention is improved.

In addition, the present invention can also form the groove as described above in the attachment 300 to be fastened to the bar holder mounting base 31. As described above, since the grooves are formed in the mounting hole 300 as well as the mounting table engaging groove 111 and the thermally conductive silicone 111b is applied to the grooves, the rollers 110a, 110b, The connection (fastening) portion between the bar holder mounting base 31 and the bar holder mounting base 31 is loosened so that the problem that the LED bar holder apparatus of the present invention is turned back (troublesome to frequently tighten) is solved .

Fig. 15 is a cross-sectional view of the LED pick-up lamp 100 having the lens structure of Fig. 11 mounted on a fishing boat.

15, when a fishing rod device including a lens 200 having a structure as shown in FIG. 11 is mounted on a fishing boat 10, a thin portion (for example, T3 in FIG. 11) , The lens 200 is configured such that the thickness of the lens 200 is adjacent to the string (center) of the fishing boat 10 rather than a thicker portion (for example, T1 in FIG. 11) (T1 in Fig. 11) is configured to be farther away from the string (center) of the fishing boat 10 than the thinner portion (e.g., T3 in Fig. 11) of the lens 200 relatively. In other words, the lens 200 is configured such that the thinner portion (for example, T3 in FIG. 11) is positioned lower than the thicker portion (for example, T1 in FIG. 11) of the lens 200. As a result, light refracted by the lens 200 is intensively irradiated on the sea surface 18 near the string of the fishing boat 10, thereby facilitating the capture of the daylight fish species.

In an embodiment of the present invention, it may be configured as shown in FIG. 15, but it may be configured in reverse. Specifically, the thick part of the lens 200 is configured to be adjacent to the string (center) of the fishing boat 10, and the thinner part of the lens 200 is positioned from the string (center) of the fishing boat 10 It can be configured to be far away. This eliminates the need to provide a separate light for an operator working on the fishing boat 10 as predetermined light is also irradiated to the fishing boat 10 side.

16 to 21 show the case where fine protrusion patterns for light scattering are formed on the inner circumferential surface 211 of the lens 200 and / or the protrusions 400 (400a, 400b, 400c) formed on the inner circumferential surface 211 Sectional view.

16 shows the fine protrusion pattern 81 formed on the entire inner circumferential surface 211 of the lens 200 shown in Fig. 9 and Fig. 17 shows the fine protrusive pattern 81 on the entire inner circumferential surface 211 of the lens 200 shown in Fig. And the fine protrusion pattern 82 is formed on the entire inner circumferential surface 211 of the lens 200 of FIG. 11 and particularly the protrusion 400. FIG. 19 is a cross- The fine protrusion patterns 84 are formed on the entire inner circumferential surface 211 of the lens 200, particularly the protrusions 400a, 400b and 400c.

Fig. 20 shows a case where fine protrusion patterns 83a are formed only on the protrusions 400 of Fig. 11, and Fig. 21 shows the case where fine protrusion patterns 84a are formed only on the protrusions 400a, 400b and 400c of Fig. will be.

The fine projection patterns 81 to 84, 83a and 84a scatter light passing therethrough so that these lights spread uniformly radially outward around the axis (perpendicular to the mounting plane of the LED chip).

The fine protrusion patterns 81 to 84, 83a and 84a are, for example, formed of fine mountains and valleys, and can uniformly spread the passing light radially.

Further, the smaller the dimension of the fine projection patterns 81 to 84, 83a and 84a, the more uniform the light can be spread. Therefore, the height of the mountain (i.e., the depth of the valley) is preferably as small as possible.

The fine protrusion patterns 81 to 84, 83a and 84a are examples of a serrated protrusion pattern, a sinusoidal protrusion pattern, a serrated protrusion pattern having a flat valley, a sinusoidal protrusion pattern having a flat valley, A flat serrated protrusion pattern, a ripple pattern, and the like. In addition to these, a number of forms capable of achieving the object of the present invention can be suitably employed.

These fine protrusion patterns 81 to 84, 83a and 84a adjust the radiation angle of the light emitted to the upper surface of the lens 200, thereby uniformly irradiating the light of the LED headlamp apparatus of the present invention. Thus, the luminance can be prevented from concentrating on the center axis of the lens 200, and thus the brightness and color uniformity of the LED headlamp apparatus of the present invention can be increased.

The present invention is also applicable to the case where the fine protrusion patterns on the protrusions 400, 400a, 400b and 400c and the fine protrusion patterns on the protrusions other than the protrusions are different in size and shape It is possible.

16 to 21, a fine protrusion pattern for light scattering is formed on the inner circumferential surface 211 of the lens 200 and / or the protrusions 400 (see FIG. 16) formed on the inner circumferential surface 211 400a, 400b, and 400c. However, the present invention is not limited thereto. Specifically, the fine protrusion patterns may be formed on the inner circumferential surface 211 of the lens 200 and / or the protrusions 400 (400a, 400b, 400c) formed on the inner circumferential surface 211 and / Can be formed on the outer peripheral surface 212.

FIG. 22A is a cross-sectional view illustrating an asymmetrical shape of a light beam emitted from the LED pick-up device according to the present invention, and FIG. 22B is a photograph showing a shape of a light beam emitted from the LED pick-up device according to the present invention. 22C is a simulation light distribution diagram using optical software for verifying the effect of the LED pick-up device according to the present invention, showing the x-axis direction light distribution (green notation) and the y-axis direction light distribution (blue notation).

As described above, the light passing through the lens 200 of the LED headlamp 100 has an asymmetric structure.

Specifically, the present invention satisfies Equation (1).

<Formula 1>

α ≠ β, α> β or α <β, 40 ° ≤γ ≤ 100 °

Here,? Is a light beam irradiation (emission) angle to be irradiated (emitted) through the lens 200, in other words, an irradiation angle of the light beam passing through the lens 200.

Is a distance from the surface 21a of the printed circuit board 122 on one side of the LED 121 to the center of the LED 121 provided on the surface of the printed circuit board 122, And the portion 21b where the irradiation is performed.

Beta is an angle from the surface 22a of the printed circuit board 122 on the other side of the LED 121 to the portion 22b where light is irradiated.

In the present invention, the asymmetrical light beam of?? Is irradiated so that the portion of the fishing line 10 close to the string (also referred to as &quot; And the light is condensed on the sea surface 18 of the &quot; B point &quot;

The structure of the lens 200 described above, particularly the fine projection patterns 81, 82, 83, 83a, 84, 84a and the projections 400, 400a to 400c and the like can be applied to the structure of FIG.

Thus, as shown in Figs. 22A to 22C, the present invention irradiates an asymmetric light beam, and the light in the gamma portion is uniformly distributed.

Fig. 23 is a perspective view of Fig. 6 viewed from a different angle, and further comprises an insulating ring 92 as compared to Fig.

24 is a detailed sectional view of an LED module and a holder case according to an embodiment of the present invention.

In the present invention, the printed circuit board (PCB) 122 may be a metal PCB, for example.

24, the LED module 120 of the present invention includes a circuit wiring layer 41 of a copper foil, an LED 121 formed on the circuit wiring layer 41, And an insulating layer 42 formed between the circuit wiring layer 41 and the metal plate 43 and electrically insulated between the circuit wiring layer 41 and the metal plate 43 .

The metal plate 43 is, for example, aluminum (Al) metal or the like.

The LED indicator device of the present invention further includes a non-conductor (insulator) 44 between the LED module 120 and the holder case 110, specifically between the metal plate 43 of the LED module 120 and the holder case 110, . &Lt; / RTI &gt; The nonconductor 44 is made of heat-transferable material.

The non-conductor 44 will now be described in more detail.

In the case where the insulating layer 42 is formed between the circuit wiring layer 41 and the metal plate 43 as described above, due to the technical limitations of the metal PCB manufacturing process and the material development of the insulating layer 42, 41 and the metal plate 43 remains at about 1.5 KV to 3 KV.

Due to such a problem, the circuit wiring layer 41 including the circuit electric input line, the metal plate 43 or the holder case 110, and the electric input line are damaged due to the shock electric (lightning, high voltage, The package is damaged.

In order to solve this problem, the present inventor inserts the non-conductor 44 between the metal plate 43 of the LED module 120 and the holder case 110. Thereby, the electrical isolation between the holder case 110 and the metal plate 43 is realized. Accordingly, it is possible to raise the insulation breakdown voltage, which is a problem, to about two to three times, and it is possible to protect the LED headlamp 100 of the present invention from surge voltage and other electric shocks.

In addition, since the nonconductor 44 also serves as a heat transfer between the metal plate 43 and the holder case 110, it is possible to prevent deterioration of the LED stick-on light device of the present invention.

FIG. 25 is a detailed sectional view of the LED module and the holder case according to another embodiment of the present invention, and is also a sectional view of FIG. 23. FIG.

 When the LED module 120 is fixed to the holder case 110 using the metal bolt 91, the LED module 120 (specifically, the metal plate 43 of the LED module 120) Electrical isolation between the case 110 and the case 110 is important. For this purpose, an insulating ring 92 made of an insulating material is formed.

23 to 25, the LED module 120, more specifically, the circuit wiring layer 41, the insulating layer 42, the metal plate 43, and the nonconductor 44 are fixed to the bolt 91, And a fastening groove for fastening the threaded portion of the bolt 91 to the inner side surface of the holder case 110 is formed. The bolts 91 may be fastened to the holder case 110 through the holes formed in the LED module 120 or the insulating ring 92 may be fastened to the LED module 120 in the state where the bolts 91 are formed on the outer circumferential surface of the bolt 91, The bolt 91 is fastened to the holder case 110 through the hole formed in the LED module 120. [ The metal plate 43 of the LED module 120 is protected by the insulating ring 92 even when the LED module 120 is fixed to the holder case 110 with the metal bolt 91. [ And the holder case 110 can be electrically isolated from each other.

Fig. 26 is a block diagram showing the control of the LED indicator 100 or the refrigerant circulation pump according to the measurement result of the temperature sensor 71. Fig.

Referring to FIG. 26, a temperature sensor 71 is formed inside the LED stick-on device.

The temperature sensor 71 measures the temperature inside the LED headlamp apparatus and the measured temperature value is transmitted to the controller 72. The controller 72 then compares the temperature value inside the LED headlamp apparatus with the first temperature And if the temperature value inside the LED bulb holder is equal to or higher than the first temperature value, the LED bulb 100 is turned off or the refrigerant circulation pump is controlled so that the refrigerant circulating in the bulb holder 31 To adjust the circulation speed.

Thereafter, when the temperature value inside the LED headlamp apparatus becomes lower than the second temperature value, the controller 72 turns on the LED headlamp 100 or controls the refrigerant circulation pump to circulate in the headlamp mount 31 The second temperature value has a value smaller than the first temperature value.

FIG. 27 is a perspective view of a reflection device 500 according to an embodiment of the present invention, and FIG. 28 is a cross-sectional view taken along line B-B 'of FIG. 27, and shows one single reflection device 500 in FIG. That is, as an example in Fig. 27, five single reflecting devices 500 having the structure as shown in Fig. 28 are arranged in the lateral direction (y-axis direction).

The present invention may further include a reflection device 500 capable of providing high-efficiency light distribution.

The reflector 500 is configured to have asymmetric light distribution characteristics so that the light emitted from the LED 121 of the LED module 120 is focused on the sea surface 18 near the strings of the fishing line 10.

The LED module 120 includes a printed circuit board 122 and a plurality of LEDs 121 disposed on the printed circuit board 122 in the M rows and N columns (where M and N are natural numbers) do.

Specifically, the LED module 120 is formed on a printed circuit board 122 having a strip shape (unit), which is elongated in the longitudinal direction (column direction, x-axis direction) A plurality (1 M) of LEDs 121 are arranged in the horizontal direction (the axial direction), and a plurality of (M) LEDs 121 are arranged in the lateral direction Structure. The LED module 120 includes a plurality of LEDs 121 arranged in a matrix of M rows and N columns (M × N (where M and N are natural numbers)) on a rectangular printed circuit board 122 It is a structure. In an embodiment of the present invention, M is 5 and N is 10, as shown in Figs.

The structure of the LED module 120 is designed so that light reflection of the reflective device 500 positioned on the LED module 120 is efficiently performed.

27 and 28, the reflection device 500 of the present invention asymmetrically reflects the light irradiated from the LED 121 disposed on the printed circuit board 122. As shown in Fig.

Specifically, the reflecting device 500 is open at the top, is elongated in the longitudinal direction (column direction, x-axis direction), and forms the light guide groove 510 which gradually increases along the traveling direction of light. Here, the light guide groove 510 of the reflection device 500 is also formed to be long in the longitudinal direction (column direction, x axis direction).

The upper part of the reflection device 500 of the present invention is installed in the direction toward the sea from the fishing boat 10.

A plurality of LEDs (LEDs) 121 are arranged at regular intervals on the bottom surface of the light guide groove 510 in the longitudinal direction (column direction, x-axis direction).

The side walls 521 and 522 of the light guide groove 510 are configured to have different inclination angles, that is, asymmetric inclination angles. That is, it has different inclined surfaces inclined outward with respect to the LED 121. As a result, the optical axis Lc of the LED module 120 can be inclined relative to the vertical axis.

The inclined angle? 1 of the first reflective sidewall 521 formed on one side of the LED 121 among the opposite side reflective sidewalls of the light guide groove 510 and the inclination angle? 2 of the second reflective sidewall 522 formed on the other side of the LED 121 are different from each other. As an example, the inclination angle [theta] 1 of the first reflective sidewall 521 is 20 to 70 [deg.] And the inclination angle [theta] 2 of the second reflective sidewall 522 is 30 to 90 [deg.].

In particular, when the inclination angle 1 of the first reflective sidewall 521 is smaller than the inclination angle 2 of the second reflective sidewall 522, the optical axis Lc of the LED module 120 is smaller And is inclined by the angle [theta].

Here, the vertical axis represents the vertical (90 degrees) direction with respect to a predetermined point (e.g., LED) on the surface of the printed circuit board 122. The inclination angle 1 of the first reflective sidewall 521 is an angle between the first reflective sidewall 521 and the surface of the printed circuit board 122 and the inclination angle 2 of the second reflective sidewall 522 is 2 reflective sidewall 522 and the surface of the printed circuit board 122.

The distance a between the first reflective sidewall 521 and the surface of the printed circuit board 122 and the distance a between the LED 121 and the second reflective sidewall 522 and the surface of the printed circuit board 122 B may be set to be the same as or different from the distance b between the point of meeting and the LED 121 and may be set to be larger than b or vice versa.

An LED seating hole (LED receiving hole) 530 may be provided as an example for seating the LED 121 arranged in one (row or column) on the bottom surface of the light guide groove 510 .

This LED seating hole (LED receiving hole) 530 is configured to correspond to the LED 121 provided on the printed circuit board 122.

The LED seating hole 530 may be configured such that the LED 121 is inserted into the printed circuit board 122 from the bottom of the printed circuit board 122.

The reflective device 500 according to the present invention, which is elongated in the longitudinal direction (column direction, x-axis direction), is detachably attached to the printed circuit board 122 in the longitudinal direction (band- .

Accordingly, the reflection device 500 of the present invention having the above-described structure can control the light distribution of light emitted from the plurality of LEDs 121.

When the fishing rod device of the present invention including the reflection device 500 having the above structure is installed on the fishing line 10, the second reflective side wall 522 is arranged at a distance from the fishing line 10 (Center) of the main body. Conversely, the first reflective sidewall 521 is configured to be away from the string (center) of the fishing boat 10 as compared to the second reflective sidewall 522 (see Fig. 31)

29 is a sectional view of a reflection device 500 according to another embodiment of the present invention.

29, a plurality of reflective protrusions 540 may be provided on the first reflective sidewall 521 and the second reflective sidewall 522 of the light guide groove 510 of the reflective device 500 according to the present invention. have.

The reflecting protrusion 540 has a shape protruding from the surfaces of the first and second reflecting sidewalls 27b and 27c and has a circular shape, an elliptical shape, or the like.

A plurality of reflection protrusions 540 are provided on the first reflection sidewall 521 and the second reflection sidewall 522 of the light guide groove 510 of the reflection device 500, Thereby improving a hot spot caused by non-uniformity of light, and also relieving the glare caused by light generated from the LED package.

30 is a cross-sectional view of the LED pick-up lamp 100 to which the reflection device of FIG. 28 is applied.

The LED earthing lamp 100 of the present invention includes a lamp configured to forward light, a plate for fixing the lamp, and the reflection device 500 for reflecting the light output from the lamp.

Here, the lamp may be a light source itself fixed to the plate or may have a configuration including a light source (e.g., an LED light source) and an LED module 120.

Examples of the light source include an incandescent lamp, a gas lamp, and a fluorescent lamp, as well as the LED light source described above.

Further, the plate is, for example, a planar type LED module 120 having a plurality of LED light sources on its front side.

The reflection device 500 is configured to have asymmetric light distribution characteristics so that the light emitted from the LED 121 of the LED module 120 is focused on the sea surface 18 near the string of the fishing line 10.

The detailed description of the structure and the like of the reflection device 500 has been made in the foregoing, and therefore will not be described here.

31 is a cross-sectional view of the LED pick-up lamp 100 to which the reflector of FIG.

31, when the fishing rod device including the reflecting device 500 having the structure as shown in FIG. 28 is installed on the fishing boat 10, the second reflecting side wall 522 is smaller in height than the first reflecting side wall 521, And the first reflecting sidewall 521 is configured to be farther away from the string or center of the fishing boat 10 than the second reflecting sidewall 522. [

As a result, light reflected by the reflecting device 500 is intensively irradiated on the sea surface 18 near the string of the fishing boat 10, thereby facilitating capture of the daylight fish species.

In an embodiment of the present invention, it may be configured as shown in FIG. 31, but it may be configured in reverse. Specifically, the first reflective sidewall 521 is configured to be closer to the string (center) of the fishing boat 10 than the second reflective sidewall 522, and the second reflective sidewall 522 is configured to be closer to the first reflective sidewall 521, (Center) of the fishing boat 10 as compared with the fishing line 10. At this time, the inclination angle 2 of the second reflective sidewall 522 is set larger than the inclination angle 1 of the first reflective sidewall 521. This is because the reflected light reflected through the first reflecting sidewall 521 is also irradiated to the fishing line 10 so that it is not necessary to provide a separate lighting lamp for the worker working on the fishing line 10.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It can be understood that

10: Fishing boat
11: vertical support
12: Horizontal support
13: LED module
18: sea level
31: Stowel stand
32: Connecting pipe
33:
41:
42: Insulation layer
43: metal plate
44: Non-conducting
50: joint part
51:
60: Packing
65: Packing insertion groove
71: Temperature sensor
72:
81, 82, 83, 83a, 84, 84a:
91: Bolt
92: Insulation ring
100: LED headlight
110: holster case
111: Mounting plate engaging groove
111b: Silicon for thermal conductivity
120: LED module
121, 121a to 121c: LED
122: printed circuit board
130: LED module mounting part
140: fastening bolt
141: Bolt coupling ball
150: AC-DC converter
200, 200 ': lens
211: inner peripheral surface
212: outer peripheral surface
300: Attachment hole
a, b, c: outer peripheral surface of the lens
T1, T2, T3: Lens thickness
400, 400a to 400c:
401: center of projection
402: center of LED
500: Reflector
510: light guide groove
521: first reflective sidewall
522: second reflective sidewall
[theta] 1: the inclination angle of the first reflective sidewall
? 2: the inclination angle of the second reflective sidewall
Lc: optical axis
530: seating hole
540: reflection projection
a: distance between the LED and the point where the first reflective sidewall and the printed circuit board meet
b: distance between the LED and the point where the second reflective sidewall and the printed circuit board meet

Claims (8)

An LED module (120) comprising a printed circuit board (122) and a plurality of LEDs (121) arranged in a matrix on the printed circuit board (122), the LED module
(110) in which the LED module (120) is installed, a heat dissipating function is provided, and a mounting groove engaging groove (111) is formed at the rear side of the lamp fixture (31); And
And an attaching part 300 for supporting the LED headlamp 100 from the rear so that the headlamp attaching base 31 is closely attached to the attaching plate engaging groove 111 formed on the rear side of the sticklet case 110,
And a heat conductive member is provided between the LED string light 100 and the string light mount 31 and between the attachment hole 300 and the string light mount 31. [ Device.
The method according to claim 1,
The LED pick-up device is further provided with an AC-DC converter 150 for converting an AC power source to a DC power source,
And the heat generated in the AC-DC converter (150) is cooled by the coolant flowing in the fixture mount (31).
The method according to claim 1,
And the refrigerant is circulated in the bar lamp mount (31) having a hollow interior.
The method of claim 3,
Wherein the refrigerant is in a liquid state such as cooling water, cooling oil or antifreeze, or in a gaseous state such as a cooling gas.
5. The method according to any one of claims 1 to 4,
The LED headlamp (100) further includes a reflective device (500) configured to emit an asymmetrical light beam,
Wherein the reflective device (500) is positioned above the LED module (120).
6. The method of claim 5,
The LED module 120 includes a printed circuit board 122 and a plurality of LEDs 121 arranged in a row and a column direction on the printed circuit board 122,
The reflective device 500 includes a light guide groove 510 that gradually increases in accordance with a traveling direction of light,
Wherein the reflective side walls of the light guide groove (510) have different inclination angles (asymmetrical inclination angles).
The method according to claim 6,
The reflector 500 is open at the top and long in the longitudinal direction (column direction)
The light guide groove 510 of the reflective device 500 is formed long in the longitudinal direction (column direction)
And a plurality of LEDs (121) are arranged on the bottom surface of the light guide groove (510) in the longitudinal direction (column direction) at regular intervals.
8. The method according to claim 6 or 7,
1 of the first reflective sidewall 521 and the inclined angle 2 of the second reflective sidewall 522 of the light guide groove 510 are 20 to 70 ° and 30 to 90 °, Wherein the light source is an LED.

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